Myogenin induces a shift of enzyme activity from glycolytic to oxidative metabolism in muscles of transgenic mice.

Physical training regulates muscle metabolic and contractile properties by altering gene expression. Electrical activity evoked in muscle fiber membrane during physical activity is crucial for such regulation, but the subsequent intracellular pathway is virtually unmapped. Here we investigate the ability of myogenin, a muscle-specific transcription factor strongly regulated by electrical activity, to alter muscle phenotype. Myogenin was overexpressed in transgenic mice using regulatory elements that confer strong expression confined to differentiated post-mitotic fast muscle fibers. In fast muscles from such mice, the activity levels of oxidative mitochondrial enzymes were elevated two- to threefold, whereas levels of glycolytic enzymes were reduced to levels 0.3-0.6 times those found in wild-type mice. Histochemical analysis shows widespread increases in mitochondrial components and glycogen accumulation. The changes in enzyme content were accompanied by a reduction in fiber size, such that many fibers acquired a size typical of oxidative fibers. No change in fiber type-specific myosin heavy chain isoform expression was observed. Changes in metabolic properties without changes in myosins are observed after moderate endurance training in mammals, including humans. Our data suggest that myogenin regulated by electrical activity may mediate effects of physical training on metabolic capacity in muscle.

Effect of centrifugation at 2G for 14 days on metabolic enzymes of the tibialis anterior and soleus muscles.

BACKGROUND: The enzyme composition of different muscle types vary greatly, leading to different changes of enzyme level caused by exposure to various stimuli. METHODS: Male Wistar rats were centrifuged at 2G in a 12-ft radius centrifuge for 14 d. Tibialis anterior (TA) and soleus muscles from four centrifuge and four control rats were analyzed for three enzymes characteristic of fast twitch muscles (phosphofructokinase, glycerol-3-phosphate dehydrogenase, and pyruvate kinase), and four enzymes characteristic of slow twitch muscles (hexokinase, mitochondrial thiolase, B-hydroxyacyl CoA dehydrogenase, and citrate synthase). RESULTS: The centrifuged TA muscles lost 15% of their weight; the corresponding soleus muscles gained 4%. Calculated on the basis of dry weight, the fast twitch enzyme activities were reduced 3-15% in the TA muscles but increased 10-23% in the soleus muscles. The slow twitch enzymes were reduced 18-30% in TA muscles but were almost unchanged in the soleus muscles. When calculated on the basis of total muscle weight, all of the enzymes in TA muscles were significantly reduced by centrifugation. In contrast, in soleus muscles, on the basis of total muscle weight, centrifugation caused an average increase of 22% in the fast twitch enzymes but only marginal changes in the slow twitch enzymes.

Glutamate and potassium stimulation of hippocampal slices metabolizing glucose or glucose and pyruvate.

Using 2-deoxyglucose phosphorylation as an index of glucose use and concentrations of selected intermediates to monitor metabolic pathways, responses of rat hippocampal slices to glutamate and K+ stimulation were examined. With glutamate, the glucose phosphorylation rate (GPR) increased, and the slices accumulated glutamate at a constant rate, for 10 min. The uptake rate at each glutamate level was matched, approximately, by the increase in GPR at that level, with 4 or 5 glutamate molecules accumulated for every glucose molecule phosphorylated. Phosphocreatine and ATP levels fell abruptly, and lactate rose, probably reflecting neuronal activity, found by others to be very brief in the presence of glutamate. K+ stimulation produced responses of phosphocreatine, ATP and lactate levels and of GPR similar to those due to glutamate. There were also prolonged changes in the levels of other metabolites: with both stimulants glucose 6-phosphate fell, and malate rose. The changes in malate may be the result of the participation of mitochondrial malate dehydrogenase in both citrate cycle and malate shuttle. Citrate and alpha-ketoglutarate rose only with K+. When pyruvate was added to the medium, resting GPR was reduced, but for both stimulants the relative increases in GPR with stimulation were the same as without pyruvate. The changes in metabolic intermediates in response to K+ were like those with glucose alone. But with glutamate, the rise in lactate was greatly diminished, and malate fell instead of rising. Glutamate interference with the transfer of both 3-carbon as well as 4- and 5-carbon intermediates from glia to neurons may explain these results. If so, this interference is greater with pyruvate supplementation than with glucose alone.

Metabolite changes associated with heat shocked avian fibroblast mitochondria.

A previous report from our laboratory (Collier et al 1993) showed that the elongated tubules of mitochondria in the cytoplasm of cultured chicken embryo fibroblasts collapsed to irregularly shaped structures surrounding the nuclear membrane after a 1 h heat shock treatment. The normal mitochondrial morphology reappeared upon removal of the thermal stress. We have now determined that several changes occurred in mitochondrial-related metabolites under these same heat shock and recovery conditions. Among these were significant decreases in the levels of fumarate and malate and increases in the amounts of aspartate and glutamate. In contrast, other intermediates of the tri-carboxylic acid cycle were unaltered as were levels of ATP and phosphocreatine. The changes observed might result from heat shock-induced changes in enzyme activities of the mitochondria, from alterations in the membrane-embedded specialized carrier proteins that transport metabolites between cytosol and mitochondria or from a disorganization of the electron-transport system normally coupled to oxidative metabolism. The rapid recovery, however, suggested that these changes were transient and readily reversible.

Changes in ATP, phosphocreatine, and 16 metabolites in muscle stimulated for up to 96 hours.

Rabbit tibialis anterior muscles were stimulated continuously at 10 Hz for periods ranging from 2 min to 96 h and were analyzed for energy reserves and metabolic intermediates. Glycogen, ATP and phosphocreatine fell rapidly during the first 5 min of stimulation. Glycogen continued to fall to very low levels, whereas ATP and phosphocreatine rose, reaching 70% of control by 1 h, despite ongoing stimulation. After 2 h, glycogen also increased, regaining control levels in 4 days. Glucose rose to 4.5 times control in 30 min and still exceeded 2.5 times control at 24 h. In the first 2 min, glycolytic intermediates, glucose 6-phosphate (G-6-P), fructose 1,6-bisphosphate, lactate, and pyruvate more than doubled and then returned to control levels or below. Malate and 3-glycerophosphate rose 600 and 200%, respectively. Both of these compounds participate in shuttling reducing equivalents from cytoplasm into mitochondria. Citrate and alpha-ketoglutarate underwent much more modest changes. Glucose 1,6-bisphosphate (G-1,6-P2) fell to one-third of control by 2 h and then rose dramatically at 4 h. At 4 days it was still twice control. The 6-phosphogluconate (6PG) doubled at 2 min, then rose to 12 times control at 2 h, fell somewhat, and peaked at 16 times control at 24 h. Aspartate and alanine both exhibited a biphasic rise in concentration, whereas glutamate fell to 30% in 15 min and rose slowly after 4 h. The rise in glucose was interpreted to be the consequence of rapid glycogenolysis together with inhibition of hexokinase by G-1,6-P2 and elevated G-6-P. Paradoxically, glycogen resynthesis apparently occurred when the glycogen synthase stimulator, G-6-P, was very low, and the glycolysis stimulator, G-1,6-P2, was high. Although G-1,6-P2 is an inhibitor of 6PG dehydrogenase, the timing of the changes in G-1,6-P2 and 6PG levels suggests that the accumulation of 6PG was initiated by some other influence.

Mitochondrial enzymes increase in muscle in response to 7-10 days of cycle exercise.

Endurance exercise training induces a significant increase in the respiratory capacity of skeletal muscle. This is reflected by a training-induced increase in mitochondrial enzyme activity. One consequence of this adaptation is that there is a decreased reliance on carbohydrate utilization with a concomitant increase in fat utilization, resulting in an improvement in endurance capacity. Recently it has been reported that 7-14 days of cycle ergometer exercise training does not induce an increase in mitochondrial enzyme levels in skeletal muscle but, nevertheless, results in smaller decreases in phosphocreatine and glycogen and smaller increases in Pi and lactate in muscle in response to the same exercise after compared with before training. However, previous studies in rats have shown that an adaptive increase in mitochondrial enzymes is already evident after only 2 days of exercise training. In view of this discrepency, the present study was performed to reevaluate the effect of short-term training (7-10 days) on mitochondrial enzymes in skeletal muscle of humans. Twelve subjects [6 men and 6 women, 27 +/- 5 (SE) yr old] underwent 7 (n = 5) or 10 days (n = 7) of cycle ergometer exercise for 2h/day at 60-70% of peak O2 consumption. Peak O2 consumption was increased by 9% (from 2.97 +/- 0.16 to 3.24 +/- 0.17 l/min) in response to training. Blood lactate levels were lower at the same absolute work rates after than before training. The activities of citrate synthase, beta-hydroxyacyl-CoA dehydrogenase, mitochondrial thiolase, and carnitine acetyltransferase were increased by approximately 30% in response to training. The results of the present study provide evidence that in humans, as in rats, the adaptive increase in mitochondrial enzymes in skeletal muscle occurs fairly rapidly in response to exercise training. They provide no support for the claim that this adaptive response is delayed for > 2 wk after the onset of training.

Alterations of intraembryonic metabolites in preimplantation mouse embryos exposed to elevated concentrations of glucose: a metabolic explanation for the developmental retardation seen in preimplantation embryos from diabetic animals.

Preimplantation mouse embryos exposed to hyperglycemia, whether in vivo or in vitro, experience delayed development from the 2-cell to blastocyst stage. By comparing metabolites from embryos exposed to high vs. normal glucose conditions, a metabolic explanation for the delayed growth pattern was sought. Fertilized 1-cell embryos obtained from superovulated B5 x CBA F1 mice were cultured for 96 h in medium containing 2.8 mM glucose (C) or in medium with added glucose to give 10 mM, 30 mM, or 52 mM glucose (HG). After incubation, each embryo was quick-frozen and freeze-dried. Metabolites were assayed by the ultramicrofluorometric technique and enzymatic cycling to obtain measurable levels in single embryos. Embryos cultured in HG exhibited 7-fold higher intracellular glucose levels than those cultured in C (C: 2.25 +/- 0.6 vs. HG: 16.61 +/- 2.4 mmol/kg wet weight; p < 0.001; C, n = 9; HG, n = 16). This accumulation of glucose was dose-related and stage-dependent. Citrate (C: 1.07 +/- 0.14 vs. HG: 1.98 +/- 0.12; p < 0.001), sorbitol (C: 0.41 +/- 0.06 vs. HG: 0.57 +/- 0.03; p < 0.01), malate (C: 0.81 +/- 0.13 vs. HG: 1.72 +/- 0.17; p < 0.001), and fructose (C: 2.1 +/- 0.3 vs. HG: 5.3 +/- 0.6; p < 0.001) were all significantly higher in HG. Also, these metabolites were highest in the most delayed embryos. Glycogen and 6-phosphogluconate levels were not significantly different. In conclusion, intraembryonic levels of glucose, and polyol pathway and Krebs cycle metabolites are elevated and correspond to the degree of developmental delay. These findings suggest that a metabolic abnormality may be responsible for retarded development experienced by embryos exposed to high glucose.

Administration of prostaglandin E1 after lung transplantation improves early graft function.

Early graft dysfunction continues to be a major clinical problem after lung transplantation. The objective of this experiment was to determine whether continuous administration of prostaglandin E1 (PGE1) after lung transplantation has a beneficial effect on early graft function. Left lung allotransplantation was performed in 10 size-matched mongrel dogs (weight, 24.4 to 31.4 kg). Lung preservation consisted of a bolus injection of PGE1 (250 micrograms) into the pulmonary artery, followed by a pulmonary artery flush with 50 mL/kg of 4 degrees C modified Euro-Collins solution. The lungs were then stored at 1 degree C for 12 hours. Left lung transplantation was performed using standard technique. The right pulmonary artery and right bronchus were ligated prior to chest closure. Animals were placed in the supine position and ventilated for 6 hours with 100% oxygen at a rate of 20 breaths/min, a tidal volume of 550 mL, and a positive end-expiratory pressure of 5 cm H2O. Animals were randomly allocated to one of two groups. Group I animals (n = 6) received continuous PGE1 infusion from the onset of implantation. The dose was gradually increased and fixed when mean systemic pressure showed a 10% decrease (mean PGE1 dose, 31.7 +/- 6.9 ng.kg-1.min-1). Group II animals (n = 4) received no PGE1. After the 6-hour assessment period, arterial oxygen tension and alveolar-arterial oxygen pressure difference were preserved in group I compared with group II (group I versus group II: arterial oxygen tension, 255.8 +/- 37.6 mm Hg versus 64.7 +/- 7.9 mm Hg [p < 0.05]; alveolar-arterial oxygen pressure difference, 411.1 +/- 70.5 mm Hg versus 597.5 +/- 1.3 mm Hg [p < 0.05]).(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of tetrodotoxin-induced neural inactivation on single muscle fiber metabolic enzymes.

Selected enzymes were measured in mixed-fiber bundles and individual fibers from rat plantaris (PL) and soleus (Sol) muscles that had undergone either 2 wk of tetrodotoxin (TTX) inactivation of the sciatic nerve, a sham operation, or were contralateral to the TTX limb. TTX disuse caused severe wasting of PL (46%) and Sol (26%) muscles and of single fibers (50% and 40%, respectively). TTX PL and Sol also had reduced (50%) glycogen content. In TTX, PL, and Sol macro samples and single fibers, the activities (mol.h-1.kg dry wt-1) of hexokinase, glycogen phosphorylase, and lactate dehydrogenase were higher, lower, and unchanged, respectively, compared with controls. Single-fiber data showed that these changes occurred in all fibers. In TTX PL macro samples, activities of glycerol-3-phosphate dehydrogenase (GPDH), pyruvate kinase (PK), malate dehydrogenase (MDH), citrate synthase (CS), beta-hydroxyacyl-CoA dehydrogenase (BOAC), and thiolase were, or tended to be, lower. Single-fiber data showed a disappearance of high-oxidative moderate glycolytic fibers (i.e., usually fast-twitch oxidative in control) and the appearance of more fibers with a metabolic enzyme profile approaching that of control slow-oxidative fibers. In TTX Sol macro samples, GPDH and PK tended to be higher, and thiolase, BOAC, CS, and MDH lower. Single-fiber data corroborated these findings and suggested the appearance of fast fibers with downregulated oxidative enzyme profiles. Our results suggest that neuromuscular activity is a major, but not the sole, determinant of the size and metabolic heterogeneity that exists in muscle cells.

Ras signaling in the activation of glucose transport by insulin.

An approach involving microinjection and microanalysis has been developed to investigate signal-transduction pathways involved in the hormonal control of metabolism. We have applied this strategy to investigate the role of Ras signaling in the acute activation of glucose transport by insulin in cardiac myocytes. Glucose transport activity was assessed by measuring the initial rate of accumulation of 2-deoxyglucose 6-phosphate (dGlc6P) in individual cells after incubation in 2-deoxyglucose. Insulin increased accumulation of dGlc6P by 3- to 4-fold, consistent with its stimulatory effect on glucose transport. Accumulation of dGlc6P was increased severalfold by microinjecting the nonhydrolyzable GTP analogue, guanosine 5'-[gamma-thio]triphosphate, which activates members of the Ras superfamily of GTP-binding proteins. Injecting activated Ha-Ras protein also mimicked insulin by increasing dGlc6P; whereas, injecting a Ras protein lacking the COOH-terminal site of fatty acylation required for Ras function was without effect. Introducing the neutralizing Ras antibody Y13-259 into cells attenuated the effect of insulin. These findings implicate Ras in the acute regulation of metabolism by insulin.

Glucose transport and phosphorylation in single cardiac myocytes: rate-limiting steps in glucose metabolism.

Microanalytic methods were used to investigate the regulation of glucose metabolism by insulin in single myocytes isolated from adult rat ventricles. Cultured myocytes were incubated with or without insulin and, with either glucose or 2-deoxyglucose (2-DG), rinsed, and freeze-dried. Individual cells were weighed and levels of 2-DG-6-phosphate (2-DG-6-P) or glucose and glucose 6-phosphate (G-6-P) were determined after enzymatic amplification. In cells incubated with 2-DG, insulin increased the level of 2-DG-6-P by as much as 30-fold, indicative of dramatic activation of glucose transport. In cells incubated with glucose, insulin increased the levels of G-6-P by approximately threefold. Increasing extracellular glucose without insulin also increased G-6-P; however, intracellular glucose concentrations were not increased, indicating that glucose transport is rate limiting in nonstimulated myocytes. In contrast, intracellular glucose concentrations were increased by over an order of magnitude by insulin, reaching 60% of the extracellular glucose concentration. Measurements of glucose and G-6-P in the same insulin-treated cells revealed that accumulation of G-6-P reached a plateau when extracellular glucose was increased > 2 mM. At this point the estimated intracellular glucose concentration was 300 microM, or approximately 10 times the Michaelis constant of hexokinase for glucose. These results indicate that in the presence of insulin and physiological concentrations of glucose, hexokinase is saturated with glucose. Consequently, the rate-limiting step for insulin-stimulated glucose utilization is glucose phosphorylation rather than glucose transport.

An unusual active hexose transport system in human and mouse preimplantation embryos.

In a metabolic study of human and mouse preimplantation embryos (preembryos), we measured glucose uptake and phosphorylation with nonradioactive 2-deoxyglucose (DG) as tracer. Initial experiments indicated an active hexose transport capacity, a property thought to be restricted in mammals to intestinal villi and kidney tubules [Baly, D. L. & Horuk, R. (1988) Biochim. Biophys. Acta 947, 571-590]. Significant findings are as follows: (i) During a 60-min incubation with a low level of DG, mouse blastocyst DG rose to levels up to 30 times that of the medium. (The intestinal active system does not transport DG [Crane, R. K. (1960) Physiol. Rev. 40, 789-825].) (ii) Active preembryo transport was not blocked (as it would have been in the intestine) by phlorizin [Alvarado, F. & Crane, R. K. (1962) Biochem. Biophys. Acta 56, 170-172 and Sacktor, B. (1989) Kidney Int. 36, 342-350] or by replacement of Na+ with choline+ or K+ [Crane (1960) and Sacktor (1989)]. (iii) Transport of DG was blocked by cytochalasin B (which is not true for the intestinal transporter). We conclude that a distinct active hexose transporter and at least one facilitated transporter are present in preembryos, perhaps appearing in tandem on different membranes during formation of the increasingly complex preembryo structure.

Enzyme activities and maturation in unstimulated and exogenous gonadotropin-stimulated human oocytes.

With the advent of new techniques of human in vitro fertilization (IVF), identifying parameters of oocyte quality to allow selection of those most likely to fertilize becomes crucial. Morphology of oocytes, which correlates positively with biological performance, is the currently utilized classification criterion. However, biological links between form and function are tenuous, and underlying mechanisms remain elusive. We investigated whether biochemical activation is quantitatively associated with the stages of maturation in ova obtained from patients undergoing gynecologic surgery during unstimulated cycles and women undergoing IVF after exogenous gonadotropin stimulation. Changes in selected enzymes from protein, lipid, and carbohydrate metabolism (hexokinase, phosphoglucomutase, glycogen synthetase, uridine diphosphoglucose pyrophosphorylase, glucose-6-phosphate dehydrogenase, cytosolic thiolase, beta-hydroxyacyl-CoA dehydrogenase, alanine aminotransferase, and aspartate aminotransferase) were determined simultaneously, in individual oocytes, utilizing a highly sensitive biochemical methodology. Several enzyme activities paralleled maturation grade and were higher in stimulated oocytes after correction for grade. These biochemical findings quantify metabolic and functional changes that increase as ova mature, possibly contributing to their reproductive performance.

Changes in alveolar oxygen and carbon dioxide concentration and oxygen consumption during lung preservation. The maintenance of aerobic metabolism during lung preservation.

The lung is the only organ to which oxygen may be supplied after its blood supply is stopped. Before this study, we were not certain whether lung cells were able to maintain aerobic metabolism with the oxygen in the alveoli during preservation. Excised rabbit lungs were used to measure changes in the concentration of oxygen and carbon dioxide in the airway and changes in glucose, glucose-6-phosphate, lactate, adenosine triphosphate, and phosphocreatine levels in the lung tissue during preservation under different conditions. Twenty-seven lungs were flushed with low-potassium dextran electrolyte solution, inflated with room air, and preserved at 1 degree C (n = 8), 10 degrees C (n = 8), or 22 degrees (n = 11) for 4, 12, or 24 hours. Eight additional lungs were inflated with 100% nitrogen and preserved at 10 degrees C for 4 (n = 4) or 24 (n = 4) hours. Oxygen levels decreased and carbon dioxide levels increased in the airway of the lungs that were inflated with room air at rates dependent on the preservation temperature. The increase of carbon dioxide in the lungs that were inflated with 100% nitrogen was very small. When the oxygen was not available in the alveoli, lactate accumulated, and adenosine triphosphate and phosphocreatine decreased in the lung tissue. We concluded that lung cells are able to maintain aerobic metabolism with the oxygen in the alveoli during preservation and that the maintenance of aerobic metabolism may be essential to maintain the optimum viability of preserved lung tissue.

A refinement of the Akabayashi-Saito-Kato modification of the enzymatic methods for 2-deoxyglucose and 2-deoxyglucose 6-phosphate.

Akabayashi et al. made a valuable modification of the enzymatic methods from our laboratory for measuring 2-deoxyglucose and 2-deoxyglucose 6-phosphate. Their modified procedure eliminates glucose and glucose 6-phosphate by conversion to fructose-1,6-bisphosphate, thereby saving two analytical steps. However, the present report describes a limitation of this new elimination procedure which is due to its unexpected reversibility, and provides an easy way to circumvent this limitation, namely heating to destroy the reagent enzymes before proceeding. The final result is a more flexible analytical scheme that is capable of measuring 2-deoxyglucose and its phosphate down to extremely low levels in the presence of up to thousandfold higher glucose concentrations. The completeness of glucose elimination eliminates both the problem of contamination of available glucose-6-phosphate dehydrogenases with 6-phosphogluconate dehydrogenase, and also the effect of the presence in this same enzyme of a trace of glucose dehydrogenase activity, which is an apparent side reaction.

Evaluation of lung metabolism during successful twenty-four-hour canine lung preservation.

We used a canine left lung allotransplantation model to evaluate 24-hour lung preservation with two different electrolyte solutions, low-potassium dextran and low-potassium dextran with 1% glucose. To investigate changes in the energy status during preservation, we analyzed the lungs for adenosine triphosphate, phosphocreatine, and several metabolites of the glycolysis pathway and the citric acid cycle: glucose, glucose-6-phosphate, lactate, citrate, and malate. We also devised and evaluated a pulmonary cooling jacket to prevent rewarming of the lung during implantation. The lungs were divided into four groups. Groups I (n = 10) and II (n = 6) were flushed with low-potassium dextran and groups III (n = 6) and IV (n = 6) were flushed with low-potassium dextran solution with 1% glucose. The cooling jacket was used for groups II and IV only. After 24-hour preservation at 10 degrees C, the left lungs were implanted into the recipient animals. Function of the transplanted left lung was assessed during temporary (10 minutes) occlusion of the contralateral pulmonary artery while both lungs were ventilated with 100% oxygen. This assessment was performed at 1 hour and at 3, 8, and 22 days after transplantation. Immediately after transplantation the arterial oxygen tension was 279 +/- 70 mm Hg in group I, 376 +/- 56 mm Hg in group II, 523 +/- 41 mm Hg in group III, and 518 +/- 50 mm Hg in group IV. The arterial oxygen tension in groups III and IV were significantly greater than in group I (p < 0.05). Of the lungs preserved with low-potassium dextran solution with 1% glucose solution, 11 of 12 (92%) showed excellent lung function (arterial oxygen tension > 300 mm Hg) at 3 days; only 10 of 16 lungs preserved with low-potassium dextran achieved this level of function. Glucose, glucose-6-phosphate, lactate, citrate and malate levels decreased significantly during 24-hour preservation with low-potassium dextran solution; they were stable with low-potassium dextran solution with 1% glucose. Adenosine triphosphate and phosphocreatine were stable for 24 hours with both low-potassium dextran and low-potassium dextran solution with 1% glucose. The cooling jacket provided uniform cooling of the lung parenchyma during implantation, and significant increase in temperature was observed in its absence, with topical cooling by cold saline solution.(ABSTRACT TRUNCATED AT 400 WORDS)

Glucose metabolism assessed with 2-deoxyglucose and the effect of glutamate in subdivisions of rat hippocampal slices.

A new approach to the study of glucose phosphorylation in brain slices is described. It is based on timed incubation with nonradioactive 2-deoxyglucose (DG), after which the tissue levels of DG and 2-deoxyglucose-6-phosphate (DG6P) are measured separately with sensitive enzymatic methods applied to specific small subregions. The smallest samples had dry weights of approximately 0.5 microgram. Direct measurements in different regions of hippocampal slices showed that within 6 min after exposure to DG, the ratios of DG to glucose in the tissue were almost the same as in the incubation medium, which simplifies the calculation of glucose phosphorylation rates and increases their reliability. Data are given for ATP, phosphocreatine, sucrose space, and K+ in specific subregions of the slices. DG6P accumulation proceeded at a constant rate for at least 10 min, even when stimulated by 10 mM glutamate in the medium. The calculated control rate of glucose phosphorylation was 2 mmol/kg (dry weight)/min. In the presence of 10 mM glutamate it was twice as great. The response to 10 mM glutamate of different regions of the slice was not uniform, ranging from 164% of control values in the molecular layer of CA1 to 256% in the stratum radiatum of CA1. There was a profound fall in phosphocreatine levels (75%) in response to 10 mM glutamate despite a 2.4-fold increase in glucose phosphorylation. Even in the presence of 1 mM glutamate, the increase in glucose phosphorylation (50%) was not great enough to prevent a significant drop in phosphocreatine content.

Effects of microgravity and tail suspension on enzymes of individual soleus and tibialis anterior fibers.

Selected enzymes of energy metabolism were measured in random individual fibers of soleus and tibialis anterior (TA) muscles from rats exposed for 2 wk to spaceflight (F) aboard COSMOS 2044 or tail suspension (T) and from synchronous controls. Average size of soleus fibers (dry weight per unit length) was reduced 37% in F and T fibers; there was little change in TA fibers. Enzyme changes were more pronounced in soleus than in TA fibers. Three enzymes characteristic of fast-twitch muscles, pyruvate kinase, glycerol-3-phosphate dehydrogenase, and 1-phosphofructokinase, were elevated in F and T soleus fibers, but changes in phosphofructokinase were not statistically significant. 3-Ketoacid-CoA transferase, characteristic of slow-twitch muscles, did not change significantly in either F or T fibers. Hexokinase, usually moderately higher in slow- than in fast-twitch muscles, increased markedly in both F and T fibers. In TA fibers analyzed for hexokinase, malate dehydrogenase, phosphohexoisomerase, and pyruvate kinase, only hexokinase and malate dehydrogenase showed significant changes. Hexokinase increased 83% in one of two T muscles. Enzyme data for TA fibers typed by myosin adenosinetriphosphatase were more informative: phosphofructokinase, phosphorylase, and glycerol-3-phosphate dehydrogenase were increased in type IIb fibers of either F or T muscles or both. Malate dehydrogenase was not changed in fibers of any type in either F or T muscle.